Number Factoring with Waves: Quantum Computation, Networking, Reaction

Presentation by: Lydell Aaron

Synopsis
This talk introduces an alternative framework for quantum computing, grounded in frequency-phase encoding using analog oscillators and basic electronic components. Rather than relying on conventional amplitude-phase modulation seen in most qubit systems, this model represents integers as sinusoidal waveforms with distinct frequencies. Prime frequencies act as basis modes, and factoring emerges through resonance and zero-crossing alignment between dividend sinusoids and prime frequency sinusoid divisors, akin to a form of analog period detection.

The architecture uses wave interference for number factorization. It also can be used for wave-based networking, simulation of wave-based reactions, and supports multi-state computing beyond binary.

While still in development, this perspective shows potential for new physical implementations of quantum algorithms and intuitive learning tools for understanding wave-based computation.

Bio
Lydell Aaron is an independent researcher, CEO and technical founder of Calective, LLC, a non-traditional defense startup, where he is developing novel analog gate-based approaches to quantum computing, tamper-resistant wireless data link communication systems, drones, and waste to energy systems. Lydell earned his B.S. in Computer Engineering from California Polytechnic State University, San Luis Obispo, where he “learned by doing” and brings years of experience in military drone development, counter drone systems, and now a patented jam-resistant wireless communications system through Calective.

Lydell approaches quantum computing from an engineering-first wave-based perspective, building models for oscillator-based systems and exploring how resonance may unlock faster, intuitive methods for number factoring. His now-published USPTO patent-pending wave-based computing architecture uses frequency-phase encoding to perform integer factoring and computation as a process of wave generation, interference, alignment, and wave-counting. He actively shares his research journey on LinkedIn, engaging both technical and non-technical audiences in the evolving dialogue around quantum technologies.